Publication detail

Numerical Model a Graphene Component for the Sensing of Weak Electromagnetic Signals

NASSWETTROVÁ, A. FIALA, P. NEŠPOR, D. DREXLER, P. STEINBAUER, M.

Original Title

Numerical Model a Graphene Component for the Sensing of Weak Electromagnetic Signals

English Title

Numerical Model a Graphene Component for the Sensing of Weak Electromagnetic Signals

Type

conference paper

Language

en

Original Abstract

The paper discusses a numerical model and provides an analysis of a graphene coaxial line suitable for sub-micron sensors of magnetic fields. In relation to the presented concept, the target areas and disciplines include biology, medicine, prosthetics, and microscopic solutions for modern actuators or SMART elements. The proposed numerical model is based on an analysis of a periodic structure with high repeatability, and it exploits a graphene polymer having a basic dimension in nanometers. The model simulates the actual random motion in the structure as the source of spurious signals and considers the pulse propagation along the structure; furthermore, the model also examines whether and how the pulse will be distorted at the beginning of the line, given the various ending versions. The results of the analysis are necessary for further use of the designed sensing devices based on graphene structures.

English abstract

The paper discusses a numerical model and provides an analysis of a graphene coaxial line suitable for sub-micron sensors of magnetic fields. In relation to the presented concept, the target areas and disciplines include biology, medicine, prosthetics, and microscopic solutions for modern actuators or SMART elements. The proposed numerical model is based on an analysis of a periodic structure with high repeatability, and it exploits a graphene polymer having a basic dimension in nanometers. The model simulates the actual random motion in the structure as the source of spurious signals and considers the pulse propagation along the structure; furthermore, the model also examines whether and how the pulse will be distorted at the beginning of the line, given the various ending versions. The results of the analysis are necessary for further use of the designed sensing devices based on graphene structures.

Keywords

Nanomaterials; graphene; signal sensing; signal transmission; signal/noise; useful signal; large model; large periodic structure

RIV year

2015

Released

04.05.2015

Publisher

SPIE-INT SOC OPTICAL ENGINEERING

Location

BELLINGHAM, WA 98227-0010 USA

ISBN

978-1-62841-639-8

Book

Proceedings of SPIE

Pages from

1

Pages to

10

Pages count

10

Documents

BibTex


@inproceedings{BUT115600,
  author="Andrea {Nasswettrová} and Pavel {Fiala} and Dušan {Nešpor} and Petr {Drexler} and Miloslav {Steinbauer}",
  title="Numerical Model a Graphene Component for the Sensing of Weak Electromagnetic Signals",
  annote="The paper discusses a numerical model and provides an analysis of a graphene coaxial line suitable for sub-micron sensors of magnetic fields. In relation to the presented concept, the target areas and disciplines include biology, medicine, prosthetics, and microscopic solutions for modern actuators or SMART elements. The proposed numerical model is based on an analysis of a periodic structure with high repeatability, and it exploits a graphene polymer having a basic dimension in nanometers. The model simulates the actual random motion in the structure as the source of spurious signals and considers the pulse propagation along the structure; furthermore, the model also examines whether and how the pulse will be distorted at the beginning of the line, given the various ending versions. The results of the analysis are necessary for further use of the designed sensing devices based on graphene structures.",
  address="SPIE-INT SOC OPTICAL ENGINEERING",
  booktitle="Proceedings of SPIE",
  chapter="115600",
  doi="10.1117/12.2177797",
  howpublished="electronic, physical medium",
  institution="SPIE-INT SOC OPTICAL ENGINEERING",
  year="2015",
  month="may",
  pages="1--10",
  publisher="SPIE-INT SOC OPTICAL ENGINEERING",
  type="conference paper"
}